RU2654895C1 - Method and device for measurement of flow rate of solid in slurry of gravitational concentrate of concentration table - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: present invention relates to measuring technology primarily in the field of mineral processing. Invention is directed to measuring the flow rate of a solid in the pulp of a gravity concentrate. Method of measuring the flow rate of a solid in the slurry of the gravity concentrate involves measuring the total width of all pulp jets of the gravity concentrate on the surface of the discharge threshold of the concentration table deck, calculation of the average value of this value for a fixed period of time, assigning the calculated value to the width of the threshold of the concentration table and, based on the result obtained, an estimate of the flow rate of a solid in the pulp of a gravitational concentrate by formula

, where Q_c – consumption of solid in the pulp of gravity concentrate, g/min, K – coefficient of proportionality, taking into account the type of concentrate used, the slope of the deck, other technical characteristics of the concentration table, L_d – controlled width of the drain threshold of the concentration table deck, t_k – a fixed interval of measurement time, b_i – the total width of all pulp jets in the measurement interval t_k. Device of measuring the flow rate of a solid in the slurry of a gravity concentrate on a concentration table contains a light emission generator, for example a laser, a beam splitter system, Forming a beam of light that scans with a given frequency, a photoreceiver of the reflected signal from the pulp streams on the drain threshold of the concentration table deck. Outputs of the photodetector are connected to the inputs of the electrical signal processing circuit, shaped by photodetector. Electrical circuit provides an electrical signal proportional to the width of all jets of the pulp flow of the gravitational concentrate at the time of measurement. Integration of the measured signal and calculation of the flow rate of the solid in the slurry of the gravitational concentrate is carried out by a computing device according to formula [1].

EFFECT: technical result is the creation of a simple and reliable method for continuous measurement of the flow rate of a solid in the pulp of gravity concentrate in the range from 50 to 600 g/min.

2 cl, 5 dwg, 1 tbl

Description

The present invention relates to measuring technique mainly in the field of mineral processing. The invention is directed to measuring the flow rate of solid in the pulp of gravity concentrate. It can be used for the extraction of gold by gravity methods from copper, copper-zinc and other gold-containing sulfide ores of non-ferrous metals, as well as for the extraction of other metals by gravity methods, for example tin.

The main parameters affecting the operating mode of the concentration tables are the material composition of the mineral raw materials, the degree of grinding (fineness) and the content and consumption of solid gravity concentrate in the pulp.

Since mineral raw materials of a fairly stable composition are processed at a specific processing plant (GO), and the degree of its grinding is established by the technological regulations, the consumption of solid gravity concentrate in the pulp becomes the main technological parameter that determines the efficiency of the concentration table [1].

The control over the consumption of solid in the pulp at most OFs is carried out manually periodically (1 time in 4 hours) using the “measuring circle” method.

This method consists in sampling the pulp at the drain of the deck of the concentration table in the intake tray, blocking the entire flow of pulp, for 1 minute. The sample taken is decanted and dried. The solid residue of the selected sample is weighed, and its mass is an indicator of solid consumption in g / min. Over such a long period of time, an uncontrolled change in the flow rate of solid can occur, which will lead either to a decrease in the productivity of the equipment or to a decrease in the extraction of metal into the concentrate, as well as to the need to change the adjustment parameters of the concentration table: the swing frequency of the deck, the course of the deck, the amount of flush water supplied to deck.

It is clear that effective control of the gravitational enrichment process on concentration tables can be achieved by continuously monitoring the consumption of solid gravity concentrate in the pulp.

The aim of the proposed invention is to provide a simple and reliable method for continuous measurement of solid flow rate in the pulp of gravity concentrate in the range (from 50 to 600 g / min).

The implementation of the proposed method is based on the revealed dependence of the separation of the pulp stream crossing the surface of the drain threshold of the concentration table deck into many separate pulp jets, and it was found that the number of jets and their width depend on the solid content in the controlled stream.

The technical feasibility of measuring the flow rate of a gravity concentrate solid in the pulp is achieved by scanning with a light beam the pulp flow crossing the surface of the drain threshold of the concentration table deck, measuring the light signal reflected from the pulp, converting it into an electrical signal and processing an electrical signal. This signal contains a sequence of pulses with different durations. Mathematical signal processing allows you to determine the flow rate of solid for a given period of time. As a result of statistical processing of the values of this signal, recorded at the time of multiple measurements of the flow rate of solid in the pulp of gravity concentrate by the method of "measuring circles", a correlation coefficient of 0.93, the possibility of using the proposed measurement method.

In accordance with the general definition of the invention and for the purpose of operational continuous non-contact measurement of solid flow in gravity concentrate, the method provides for: measuring the total width of all pulp jets of gravity concentrate on the surface of the drain threshold of the deck of the concentration table, calculating the average value of this value for a fixed period of time, assigning the calculated values to the width of the threshold of the deck of the concentration table and, based on the result, an estimate of the consumption of solid in the pool ne formula gravity concentrate

where Q _c is the flow rate of solid in the pulp gravity concentrate, g / min,

K - coefficient of proportionality, taking into account the type of concentrate used, the slope of the deck, other technical characteristics of the concentration table,

L _d is the controlled width of the drain threshold of the deck of the concentration table,

t _k is a fixed measurement time interval,

b _i - the total width of all pulp jets in the measurement interval t _k .

In practice, the pulp stream crossing the deck surface of the concentration table contains many individual pulp jets of various widths.

Figure 1 presents a diagram of the implementation of a method for measuring solid flow rate in a pulp of gravity concentrate, where it is indicated:

1 - deck concentration table,

2 - laser radiation generator,

3 - beam splitting system,

4 - drain threshold pulp gravity concentrate,

5 - photodetector,

6 is an electrical circuit for processing signals generated by a photodetector,

7 - computing device

8 - recording device,

9 - a chute for receiving pulp of gravity concentrate

f1, f2, f3 - conventional image scan of the laser beam,

f4, f5, f6 - radiation flux reflected from the surface of the pulp of gravity concentrate.

The measurement of solid flow rate in the pulp of gravity concentrate is as follows. The initial mineral pulp enters the deck of the concentration table 1, where there is a gravitational separation of minerals depending on their density. The higher density gold-containing gravity concentrate enters the drainage threshold of the concentration table, and the gangue with small particles of gold is washed off with water into the side tray for further extraction of small fractions of gold by flotation.

The laser radiation generator 2 directs the light beam to the beam-splitting system 3, which forms a scanning stream of light radiation (f1, f2, f3) and directs it to the drain threshold 4 of the deck of the concentration table 1, through which the pulp overflows the gravity concentrate. The radiation flux (f4, f5, f6) reflected from the surface of the pulp being drained enters the photodetector 5. The outputs of the photodetector are connected to the inputs of the signal processing electric circuit 6. A signal is generated at the output of the electric circuit 6, which is proportional to the total width of all jets of the gravity concentrate pulp stream. The integration of the measured signal and the calculation of the solid content in the pulp of gravity concentrate is performed by the computing device 7 and is recorded by the device 8.

The reflected signal from the pulp jets received by the photodetector 5 has the form shown in Figure 2.

The photodetector signal is received and processed using a computing device 7, for example, a PIC 16C773 type microcontroller, and an averaged signal filtered out from noise is generated at the output of the computing device, which is proportional to the flow rate of solid gravity concentrate in the pulp.

Checking the effectiveness of the method for measuring the flow rate of gravity concentrate in the pulp and the possibility of its technical implementation was carried out on the concentration table SKO-15 of the beneficiation plant of the Urup Mining and Processing Plant.

In this production, pulp from short-cone cyclones enters the concentration table, where it is divided into gravity concentrate and flotation pulp.

The drain threshold of the concentration table deck was scanned by a laser beam with a frequency of 8 Hz with a scan of the radiation width in the range 350–400 mm.

The appearance of the device that implements the method of measuring the flow rate of solid gravity concentrate in the pulp, its installation opposite the drain threshold of the deck of the concentration table is shown in Figure 3.

A fragment of recording the readings of solid consumption by recording device 8 in the pulp of a gravity concentrate at the drain threshold of a concentration table deck recorded at CJSC Urupsky GOK is shown in Figure 4.

Management of the concentration table was carried out in manual mode. The maximum increase in solid flow rate is caused by a stepwise change in the flow rate of wash water during an active experiment to determine the dynamic characteristics of the control object.

To build a calibration graph, an active experiment was conducted with the concentration table controlled in manual mode. A change in the flow rate of the gravity concentrate in the pulp was made by a stepwise change in the supply of the initial mineral pulp and the flow rate of flushing water during an active experiment.

At control points, gravity concentrate pulp samples were taken using the “measuring circle” method to determine the flow rate of solid and at the same time the readings of the measuring device were recorded

The results of the active experiment are presented in Table 1.

According to the experiment, a calibration graph is constructed, shown in Figure 5, on which the values of solid flow rate in the pulp of gravity concentrate are plotted along the ordinate axis, and the readings of the measuring device along the abscissa axis.

The squares mark the control points obtained by sampling the pulp using the "measuring circle" method, while recording the readings of the measuring device that implements the proposed measurement method.

On the calibration graph, an almost linear dependence of the values of the flow rate of the solid content in the pulp of the gravity concentrate obtained by the method of "measuring circles" and the readings of the measuring device is visible. The technical result is expressed in increasing the productivity of the concentration table and the consistently high quality of gravity concentrate, which confirms the effectiveness and reliability of the proposed measurement method.

Literature

1. S.I. Polkin "Enrichment of non-ferrous metal ores", Moscow, ed. Subsoil, 1983

Claims (8)

1. The method of measuring the flow rate of solid gravity concentrate in the pulp on the concentration table, which consists in the fact that on the surface of the drain threshold the decks of the concentration table fix the total width of all jets of pulp of the gravity concentrate, calculate the average value of this value for a fixed period of time, relate the calculated value to the width the threshold of the deck of the concentration table and the result is used to judge the consumption of solid gravity concentrate in the pulp for this fixed period formula webbings

where Q _c is the flow rate of solid in the pulp gravity concentrate, g / min, K - coefficient of proportionality, taking into account the type of concentrate used, the slope of the deck, other technical characteristics of the concentration table, L _d is the width of the drain threshold of the deck of the concentration table, t _k is a fixed measurement time interval, b _i - the total width of all pulp jets in the measurement interval t _k . 2. A device for measuring the flow rate of solid gravity concentrate in a pulp on a concentration table, containing a light radiation generator, for example a laser, a beam splitter system, generating a stream of light radiation scanning at a given frequency, a photodetector of the reflected signal from the pulp jets on the drain threshold of the concentration table deck, and outputs the photodetector is connected to the inputs of the electrical circuit for processing signals generated by the photodetector, providing an electrical signal, prop the width of all streams of gravity concentrate pulp stream at the moment of measurement, integration of the measured signal and calculation of solid flow rate in the pulp of gravity concentrate is performed by a computing device according to the formula [1].

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